Wednesday, January 15, 2014

[Press Release University of Amsterdam] Despite their genetic proximity, human and non-human primates differ in their capacity for beat induction, which is the ability to perceive a regular pulse in music or auditory stimuli and accordingly align motor skills by way of foot-tapping or dancing.

Also referred to as ‘rhythmic entrainment’, this ability is specific to humans and certain bird species, but is surprisingly enough not obvious in non-human primates. These are the findings of researchers from the University of Amsterdam and the National Autonomous University of Mexico (UNAM), whose new hypothesis, the ‘gradual audiomotor evolution hypothesis’, was recently published in the scientific journal Frontiers in Neuroscience.

Gradual audiomotor evolution hypothesis

The gradual audiomotor evolution hypothesis accommodates the fact that non-human primates’ (i.e., macaques) performance is comparable to humans in single interval tasks such as interval reproduction, categorisation and interception, but show differences in multiple interval tasks such as rhythmic entrainment, synchronisation and continuation. The hypothesis is also in line with the observation that macaques can apparently synchronise in the visual domain, but show less sensitivity in the auditory domain. Finally, while macaques are sensitive to interval-based timing and rhythmic grouping, the absence of strong coupling between the auditory and motor system of non-human primates might explain why macaques cannot rhythmically entrain in the way humans do.

Timing networks in the primate brain

Functional imaging studies in humans have revealed that the motor cortico-basal ganglia-thalamo-cortical circuit (mCBGT) is not only involved in sequential and temporal processing, but also in rhythmic behaviours such as music and dance, where auditory modality plays a critical role. The mCBGT circuit, however, seems to be less engaged in audiomotor integration in monkeys than in humans. While in humans different cognitive mechanisms are active for interval-based timing versus beat-based timing, with beat perception being dependent on distinct parts of the timing network in the brain, the anterior prefrontal CBGT and the mCBGT circuits in monkeys might be less viable to multiple interval structures, such as a regular beat.

Recent findings weaken the vocal learning hypothesis

The gradual audiomotor evolution hypothesis is an alternative to the well-known ‘vocal learning hypothesis’, which suggests that only species who can mimic sounds share the ability for beat induction. Because recent empirical findings have challenged this hypothesis, an alternative was needed.